Sostaric Simon M, Skinner Sandford L, Brown Malcolm J, Sangkabutra Termboon, Medved Ivan, Medley Tanya, Selig Steve E, Fairweather Ian, Rutar Danny, McKenna Michael J
Muscle, Ions and Exercise Group, Centre for Ageing, Rehabilitation, Exercise and Sport, School of Human Movement, Recreation and Performance, Victoria University, Melbourne, Victoria, Australia.
J Physiol. 2006 Jan 1;570(Pt 1):185-205. doi: 10.1113/jphysiol.2005.094615. Epub 2005 Oct 20.
Alkalosis enhances human exercise performance, and reduces K+ loss in contracting rat muscle. We investigated alkalosis effects on K+ regulation, ionic regulation and fatigue during intense exercise in nine untrained volunteers. Concentric finger flexions were conducted at 75% peak work rate (3 W) until fatigue, under alkalosis (Alk, NaHCO3, 0.3 g kg(-1)) and control (Con, CaCO3) conditions, 1 month apart in a randomised, double-blind, crossover design. Deep antecubital venous (v) and radial arterial (a) blood was drawn at rest, during exercise and recovery, to determine arterio-venous differences for electrolytes, fluid shifts, acid-base and gas exchange. Finger flexion exercise barely perturbed arterial plasma ions and acid-base status, but induced marked arterio-venous changes. Alk elevated [HCO3-] and PCO2, and lowered [H+] (P < 0.05). Time to fatigue increased substantially during Alk (25 +/- 8%, P < 0.05), whilst both [K+]a and [K+]v were reduced (P < 0.01) and [K+]a-v during exercise tended to be greater (P= 0.056, n= 8). Muscle K+ efflux at fatigue was greater in Alk (21.2+/- 7.6 micromol min(-1), 32 +/- 7%, P < 0.05, n= 6), but peak K+ uptake rate was elevated during recovery (15 +/- 7%, P < 0.05) suggesting increased muscle Na+,K+-ATPase activity. Alk induced greater [Na+]a, [Cl-]v, muscle Cl- influx and muscle lactate concentration ([Lac-]) efflux during exercise and recovery (P < 0.05). The lower circulating [K+] and greater muscle K+ uptake, Na+ delivery and Cl- uptake with Alk, are all consistent with preservation of membrane excitability during exercise. This suggests that lesser exercise-induced membrane depolarization may be an important mechanism underlying enhanced exercise performance with Alk. Thus Alk was associated with improved regulation of K+, Na+, Cl- and Lac-.
碱中毒可提高人体运动能力,并减少收缩期大鼠肌肉中的钾离子流失。我们研究了碱中毒对9名未经训练的志愿者在剧烈运动期间钾离子调节、离子调节和疲劳的影响。在碱中毒(Alk,碳酸氢钠,0.3 g·kg⁻¹)和对照(Con,碳酸钙)条件下,以75%的峰值工作率(3 W)进行同心手指屈曲运动直至疲劳,两种条件相隔1个月,采用随机、双盲、交叉设计。在静息、运动和恢复期间抽取肘前深静脉(v)和桡动脉(a)血样,以确定电解质、液体转移、酸碱和气体交换的动静脉差异。手指屈曲运动对动脉血浆离子和酸碱状态几乎没有影响,但会引起明显的动静脉变化。碱中毒使[HCO₃⁻]和PCO₂升高,[H⁺]降低(P < 0.05)。碱中毒期间疲劳时间显著增加(25±8%,P < 0.05),而运动期间[K⁺]a和[K⁺]v均降低(P < 0.01),运动期间[K⁺]a-v趋于更大(P = 0.056,n = 8)。碱中毒时疲劳时肌肉钾离子外流更大(21.2±7.6 μmol·min⁻¹,32±7%,P < 0.05,n = 6),但恢复期间钾离子摄取峰值率升高(15±7%,P < 0.05),提示肌肉钠钾ATP酶活性增加。碱中毒在运动和恢复期间引起更大的[Na⁺]a、[Cl⁻]v、肌肉氯离子内流和肌肉乳酸浓度([Lac⁻])外流(P < 0.05)。碱中毒时较低的循环[K⁺]以及更大的肌肉钾离子摄取、钠离子输送和氯离子摄取,均与运动期间膜兴奋性的维持一致。这表明较小的运动诱导膜去极化可能是碱中毒增强运动能力的重要机制。因此,碱中毒与钾离子、钠离子、氯离子和乳酸的调节改善有关。
